A chest drainage container for withdrawing and collecting certain body fluids from within a patient's chest cavity includes means for tolerating the container being accidentally tipped over. To provide such means, some example containers disclosed in this patent merely involve modifying the plastic injection mold of an existing chest drainage container. In some examples, certain partitions and vents are integrally formed in the container's main body. In the event of a tip-over occurrence, the partitions trap collected fluid within their appropriate collection chambers to help prevent inter-chamber mixing of fluid. During normal operation, the vents enable a pocket of otherwise trapped air to escape from within the enclosed collection chambers as incoming body fluid displaces the air. In some examples, under certain conditions, the vent releases gaseous fluid at a volumetric flow that is about 30 times greater than what the vent releases of liquid fluid during a tip-over event.

An air leak detection device is applied to a thoracic cavity drainage system which, by using negative pressure generated by a vacuum source, aspirates gas in the thoracic cavity of a patient via a water seal chamber in which liquid is received. The pressure between the vacuum source and the water seal chamber is measured by a pressure sensor, and the occurrence of air bubbles created in the water seal chamber is detected on the basis of fluctuations of this pressure.

A system for optimizing guide values, particularly in the field of infant feeding with mother's milk and/or in the field of medical drainage, which includes at least one first data set which has at least one first data group assigned to a first target group. The system also has a second data set, with at least one second data group assigned to a second target group. First data of the first target group are stored in the at least one first data group and second data of the second target group are stored in the at least one second data group. A data processing unit is used for processing the first and second data and for output of the guide values to the second target group. The data processing unit is formed in order to receive new data generated on the basis of the output of the guide values to the second target group and on the basis of the use of these guide values in the second target group and in order to convert the first data set on the basis of these new data for the purpose of optimizing future guide values.

A system (1) for collecting liquid, including a main collecting chamber (10), a main duct section (11, 12, 13) connected to the main collecting chamber (10) in a fluid-communicating manner, and an auxiliary collecting chamber (20, 30, 40). The system (1) has an auxiliary duct section (21, 38, 39) connected to the auxiliary collecting chamber (20, 30, 40) in a fluid-communicating manner for connection to the main duct section (11, 12, 13). The main duct section (11, 12, 13) and the auxiliary duct section (21, 38, 39) form a duct (35, 36, 37) when the main duct section is connected to the auxiliary duct section. A water-soluble closing component (14, 15, 16) closes the duct (35, 36, 37). A hygienic collecting device for liquid, which has a short evacuation time and a flexible collection volume, is provided with the system (1).

The invention relates to a chest drainage system (100) for creating and maintaining a sub-atmospheric pressure within the pleural cavity and/or the mediastinum of a patient (P). The system has a chest drainage unit (CDU, 10) with an internal cavity (C) having a first chamber part (C1, 11) and a second chamber part (C2, 12) with an air outlet from the CDU, and a liquid seal chamber (LSC, 13). The second chamber part (C2, 12) of the chest drainage unit is connected to a carbon dioxide sensor (CO2S, 15) for detecting carbon dioxide in any air passing through the liquid seal chamber (LSC, 13), the carbon dioxide sensor being capable of detecting carbon dioxide by a visible color change from a chemical reaction occurring in the carbon dioxide sensor between carbon dioxide and a detector reactant (DC) positioned in the carbon dioxide sensor. Preliminary test performed by the inventor have demonstrated that the present invention is very effective in determine whether, or not, carbon dioxide is present in the air passing through the chest drainage unit, this information being highly important in the subsequent decision of continuing the treatment with the chest drainage system.

A system includes a chest tube drainage system comprising a first chamber in fluid communication with a port connectable to a chest tube, a second chamber in fluid communication with a port connectable to a suction device, and a fluid seal connected to and disposed between the first chamber and the second chamber. The system also includes one or more gas sensors attached to the chest tube drainage system, the one or more gas sensors configured to detect at least one of gaseous carbon dioxide and gaseous oxygen, a controller connected to the one or more gas sensors, and at least one indicator coupled to the controller. The controller is configured to determine if a threshold level of carbon dioxide is exceeded, and to activate the at least one indicator if the threshold level of carbon dioxide is not exceeded.

A system includes a chest tube drainage system comprising a first chamber in fluid communication with a port connectable to a chest tube, a second chamber in fluid communication with a port connectable to a suction device, and a fluid seal connected to and disposed between the first chamber and the second chamber. The system also includes one or more gas sensors attached to the chest tube drainage system, the one or more gas sensors configured to detect at least one of gaseous carbon dioxide and gaseous oxygen, a controller connected to the one or more gas sensors, and at least one indicator coupled to the controller. The controller is configured to determine if a threshold level of carbon dioxide is exceeded, and to activate the at least one indicator if the threshold level of carbon dioxide is not exceeded.

A thorax drainage device for aspirating fluids from a pleural cavity of a patient using underpressure has a fluid collection container for collecting the aspirated fluids and a drainage tube for connecting the fluid collection container to the pleural cavity of the patient. The fluid collection container is connectable to a vacuum source, in order to generate an underpressure in the fluid collection container. The thorax drainage device has an adjustable mechanism for attenuating pressure differences during the respiration of the patient, this mechanism being adjustable independently of a suction capacity of the vacuum source. This device permits a gradual expansion of the lung without risk of injury and thus prepares the lung for the completion of the drainage.